KR102507995B1 - Structure of bi-directional low-voltage rack - Google Patents

Abstract

In the present invention, when replacing a transformer, a plurality of bi-directional low-voltage racks 30 installed via a cradle 10 on one side of an electric pole in a state of excluding a mobile uninterruptible transformer car and a bypass cable that have been conventionally used, A, B, Since it is a structure that secures the stability of uninterruptible power supply by connecting low-voltage cables (1) of phases C and N and temporary cables (3), it simplifies high-voltage work to prevent safety accidents, shorten construction time and reduce labor costs. It can be done.

Description

Bidirectional low-voltage rack structure {STRUCTURE OF BI-DIRECTIONAL LOW-VOLTAGE RACK}

The present invention relates to a bi-directional low-voltage rack structure, and more particularly, to secure the stability of uninterruptible power supply by connecting low-voltage cables of phases A, B, C, and N with temporary cables by means of a bi-directional low-voltage rack when replacing a transformer. It is about the rack structure.

In general, underground distribution lines use 229KV special high voltage (primary side) supplied from power plants through transmission lines when supplying power to various household or industrial facilities, and 220V/380V low voltage (secondary side) suitable for various facilities for home or industrial use. A ground transformer is used as a means of stepping down the voltage to supply to the side).

Among these ground transformers, an elbow connector is connected to an end of a primary-side extra-high voltage cable to which extra-high voltage is supplied, and the elbow connector is connected to a primary-side bushing. In addition, a connection terminal is connected to the end of the secondary cable to which the low voltage is supplied, and the connection terminal is connected to the secondary side bushing. Here, the secondary side connection terminal to which the low-voltage cable is connected is divided into an integral type in which the bushing is integrally coupled and a separate type in which the bushing is screwed together.

In addition, if an abnormality (failure) occurs in the transformer due to aging or overload, the ground transformer installed in this way must be replaced with a transformer that operates normally. Replace ground transformer.

In particular, when the ground transformer is disconnected, the transformer is replaced in a temporary power outage state in which the power of the transformer is cut off, or the transformer is exchanged in a state in which power is continuously supplied to the customer by continuously connecting and connecting the power of the transformer in a live state.

At this time, group consumers such as apartments and buildings are equipped with special high-voltage power receiving facilities and supply electricity individually, but when electrical equipment fails, power outages occur in all or part of the building, and in some cases, long-term power outages may occur.

In this way, a mobile uninterruptible transformer car is mobilized to supply temporary power in case of a long power outage, and a low voltage cable is installed between the secondary cable of the mobile uninterruptible transformer car and the low voltage distribution panel of the building during power outage.

Mobile uninterruptible transformer car is an uninterruptible method exclusive vehicle designed to perform uninterruptible work to supply power to low-voltage customers when replacing or relocating a transformer in operation, or to be used for temporary emergency recovery in the event of a burnt out or defective transformer. When connecting the low-voltage cable installed from the head of the secondary cable of the mobile uninterruptible transformer car to the low-voltage distribution panel of the building in power failure, if there is no separate connection terminal block, temporary power supply facilities such as one utility pole and low-voltage rack are constructed to supply power. do. In this case, construction of temporary power supply facilities such as electric poles requires a lot of equipment, manpower and time, as well as a lot of construction costs, resulting in many problems in prompt power supply.

In addition, there is a problem in that the head of the secondary cable of the mobile uninterruptible transformer car is easily loosened due to an external impact, resulting in a recurrence of power failure, which causes more civil complaints. In particular, when using a mobile uninterruptible transformer car, not only does it take an excessive amount of construction time, such as bypass cable indirect live wire work, but there is a risk of safety accidents due to complicated processes and excessive labor costs.

Republic of Korea Patent Publication No. 1999-0030585 (1999.05.06.)

An object of the present invention is proposed to solve the problems in view of the existing problems, and to prevent safety accidents due to the simplification of high-voltage work that does not use a portable uninterruptible transformer car and a bypass cable when replacing a transformer, while preventing construction time It is an object of the present invention to provide a bi-directional low-pressure rack structure that can reduce labor cost as well as shortening.

A bi-directional low-voltage rack structure according to an embodiment of the present invention for solving the above technical problem includes a cradle installed on an electric pole; A plurality of rack cases each fixed to the cradle at regular intervals up and down; Left and right connection terminals fixed at the center of the rack case at regular intervals on the left and right, respectively; a switch unit installed in the center of the rack case to connect or disconnect the left connection terminal and the right connection terminal; a metal left connection terminal coupled to the charging part of the low voltage cable and inserted through a conduit opened on the left side of the rack case to be connected to the left connection terminal; and a metal right connection terminal coupled to the charging part of the temporary cable and inserted through a conduit opened on the right side of the rack case to be connected to the right connection terminal.

As another embodiment, it is characterized in that female threaded surfaces are formed on the inner diameters of the plurality of rack cases of the present invention.

As another embodiment, a plurality of rack cases of the present invention is characterized in that the rear center is fixed to the cradle, respectively, via a bracket.

As another embodiment, it is characterized in that the cover is installed at the left and right ends of the plurality of rack cases of the present invention.

As another embodiment, the switch unit of the present invention is characterized in that it comprises a knob rotatably supported so as to pass through the front center of the rack case.

As another embodiment, the switch unit of the present invention is characterized in that it includes a rotating plate for simultaneously connecting or disconnecting the left connection terminal and the right connection terminal inside the rack case.

As another embodiment, the left connection terminal of the present invention, a first screw rod inserted to a predetermined depth of the rack case along the female screw surface through one end of the rack case; and a protrusion integrally formed at the center of the inner end of the first threaded rod to be connected to or separated from the switch unit.

As another embodiment, the right connection terminal of the present invention, a first screw rod inserted to a predetermined depth of the rack case along the female screw surface through one end of the rack case; and a protrusion integrally formed at the center of the inner end of the first threaded rod to be connected to or separated from the switch unit.

As another embodiment, the left connection terminal of the present invention is inserted along the female screw surface through one end of the rack case to a certain depth of the rack case, and the second screw is connected to the first screw rod of the left connection terminal. Sabong; and a sleeve integrally protruding from the center of the outer end of the second threaded rod and compressed so that the charging part of the low voltage cable is inserted and fixed.

As another embodiment, the right connection terminal of the present invention is inserted along the female threaded surface through one end of the rack case to a predetermined depth of the rack case, and the second screw is connected to the first screw rod of the left connection terminal. Sabong; and a sleeve integrally protruding from the center of the outer end of the second threaded rod and compressed so that the charging part of the temporary cable is inserted and fixed.

The present invention excludes the mobile uninterruptible transformer car and bypass cable that have been conventionally used when replacing a transformer, and low voltage cables of phases A, B, C, and N are installed on one side of an electric pole through a plurality of bi-directional low voltage racks via a cradle. Since it is a structure that secures the stability of uninterruptible power supply by connecting with and temporary cables, safety accidents are prevented due to the simplification of high-voltage work, and at the same time, construction time and labor costs can be reduced.

1 is a field photograph of a transformer replacement work state using a conventional mobile uninterruptible transformer car and bypass cable indirect live wire work;
Figure 2 is an overall perspective view showing a bi-directional low-pressure rack according to the present invention;
3 and 4 are perspective views showing before and after use of a connection sleeve used when connecting a low voltage cable and a temporary cable to a bi-directional low voltage rack according to the present invention, respectively;
5 is a cross-sectional view showing a state before the low-voltage cable and the temporary cable are temporarily connected to the bi-directional low-voltage rack according to the present invention;
6 is a cross-sectional view showing a state in which low-voltage cables and temporary cables are connected to a bi-directional low-voltage rack according to the present invention;
7 is an overall construction state diagram in which low-voltage cables and temporary cables are connected to a two-way low-voltage rack according to the present invention.

Hereinafter, in order to fully understand the present invention, a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 7 in the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the examples described in detail below. Accordingly, the shapes of elements in the drawings may be exaggerated to emphasize a clearer explanation. It should be noted that in each drawing, the same configuration may be indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

2 to 7, the bi-directional low-voltage rack structure according to an embodiment of the present invention includes an insulator cradle 10 installed on an electric pole; A plurality of bi-directional low voltages that are fixed to the cradle (10) at regular intervals up and down and connect or separate the charging part of the low voltage cable (1) inserted through the left end and the charging part of the temporary cable (3) inserted through the right end. It includes a rack 30.

That is, the plurality of bidirectional low voltage racks 30 include a plurality of insulator rack cases 32; Left and right connection terminals 50a and 50b made of metal fixed to the center of the rack case 32 at regular intervals therebetween; A switch unit 40 installed in the center of the rack case 32 to connect or disconnect the left connection terminal 50a and the right connection terminal 50b; A left connection terminal 60a made of metal connected to the charging part of the low voltage cable 1 and inserted through a conduit opened on the left side of the rack case 32 to be connected to the left connection terminal 50a; and a metal right connection terminal 60b coupled to the charging part of the temporary cable 3 and inserted through a conduit opened on the right side of the rack case 32 to be connected to the right connection terminal 50b.

The left and right connection terminals 50a and 50b and the left and right connection terminals 60a and 60b are screwed into the inner diameter of the plurality of rack cases 32 to form an internal constant of the rack case 32. It is configured in the form of an insulator pipe on which a female threaded surface 32a is formed to be moved and coupled to a depth.

The plurality of rack cases 32 are each fixed to the front of the cradle 10 via the bracket 20 of the rear center of the insulator.

An insulator cover 34 is installed at the left and right ends of the plurality of rack cases 32, and the cover 34 is hinged to open and close the left and right end inner diameters of the rack case 32, respectively. It is desirable to configure

The switch unit 40 includes an insulator knob 42 rotatably supported so as to pass through the front center of the rack case 32; And a metal rotating plate 44 fixed to the end of the knob 42 inside the rack case 32 to simultaneously connect or separate the left connection terminal 50a and the right connection terminal 50b, At the edge of the rotary plate 44, when the knob 42 is rotated 90 degrees in one direction, a part of the edge of the rotary plate 44 is the protrusion 54a of the left connection terminal 50a and the projection of the right connection terminal 50b. It is preferable that symmetrical concave portions are formed at intervals of 180 degrees so as to be separated from (54b) and cut off power supply.

The left and right connection terminals 50a and 50b and the left and right connection terminals 60a and 60b are preferably made of copper having good conductivity.

The left connection terminal (50a), a first screw rod (52a) is inserted to a predetermined depth of the rack case 32 along the female screw surface (32a) through one end of the rack case (32); and a protrusion 54a protruding from the center of the inner end of the first screw rod 52a with a predetermined length along the length direction of the first screw rod 52a to be connected to or separated from the switch unit 40. do.

The right connection terminal (50b) is, through the other end of the rack case 32 ride the female threaded surface (32a) is inserted to a predetermined depth of the rack case 32, respectively a first screw rod (52b); and a protruding portion 54b formed at the center of the inner end of the first threaded rod 52b to protrude with a predetermined length along the longitudinal direction of the first threaded rod 52b to be connected or separated from the switch 40. do.

At this time, it is preferable that the first threaded rod 52a and the first threaded rod 52b have the same diameter and length, and a male threaded surface is formed on an outer circumferential surface so as to move along the female threaded surface 32a.

It is preferable that the protrusions 54a and 54b have quadrangular circumferences so as to increase a contact area with the rotating plate 44 of the switch unit 40 .

The left connection terminal 60a is inserted through one end of the rack case 32 along the female threaded surface 32a to a predetermined depth of the rack case 32, and is inserted to a predetermined depth of the left connection terminal 50a. a second threaded rod 62a connected to the first threaded rod 52a; and a sleeve 64a protruding from the center of the outer end of the second screw rod 62a with a predetermined length along the longitudinal direction of the second screw rod 62a and compressing the charging part of the low voltage cable 1 to be inserted and fixed. ).

The right connection terminal 60b is inserted through the other end of the rack case 32 along the female threaded surface 32a to a predetermined depth of the rack case 32, and the right connection terminal 50b a second threaded rod 62b connected to the first threaded rod 52b; and a sleeve 64b protruding from the center of the outer end of the second threaded rod 62b with a certain length along the length direction of the second threaded rod 62b and being compressed so that the charging part of the temporary cable 3 is inserted and fixed. ).

At this time, it is preferable that the diameter and length of the second threaded rod 62a and the second threaded rod 62b are the same, and a male threaded surface is formed on an outer circumferential surface to move along the female threaded surface 32a.

The sleeves 64a and 64b are preferably formed in a cap shape having the same diameter and length.

In order to replace the transformer in an uninterruptible power supply state by connecting the low voltage cables 1 and temporary cables 3 of phases A, B, C, and N using the plurality of bidirectional low voltage racks 30 of the present invention configured as described above, First, as shown in FIG. 3, the charging part of the low voltage cable 1 and the charging part of the temporary cable 3 are inserted into the sleeves 64a and 64b protruding to one side of the left and right connection terminals 60a and 60b, respectively, After connecting as shown in FIG. 4, the second screw rods 62a and 62b protruding to the other side of the left and right connection terminals 60a and 60b are connected to both left and right sides of the rack case 32 as shown in FIG. Each is inserted through the right side and rotated in one direction at the same time.

At this time, the second threaded rods 62a and 62b ride the female threaded surface 32a in a state of engagement with the female threaded surface 32a formed on the inner diameter of the rack case 32, respectively, as shown in FIG. 6, and the inside of the rack case 32 As it is fastened to move to the center, it is in close contact with the first threaded rods 52a and 52b of the left and right connection terminals 50a and 50b already fastened to the inner center of the rack case 32, so that it cannot move anymore and stops. By doing so, the second threaded rods 62a, 62b and the first threaded rods 52a, 52b are connected in a state in which power can be supplied.

And the sleeves 64a and 64b connected to the charging part of the low-voltage cable 1 and the charging part of the temporary cable 3, respectively, allow the second threaded rods 62a and 62b to pass through the inside of the rack case 32 to the first As much as the moving distance connected to the screw rods 52a and 52b, it is towed and protected to be located on the left and right sides of the rack case 32, thereby preventing a mixed contact accident.

In this state, when the knob 42 of the switch unit 40 installed at the outer center of the rack case 32 is rotated 90 degrees in one direction, the knob 42 at the inner center of the rack case 32 as shown in FIG. As the rotating plate 44 connected to is rotated, the protrusion 54a protrudes from the first screw rod 52a of the left connection terminal 50a and the protrusion part protrudes from the first screw rod 52b of the right connection terminal 50b ( 54b), the low-voltage cable (1) on both sides is connected through the temporary cable (3) as shown in FIG. After that, you can safely replace it with a new transformer.

As such, the present invention is A by a plurality of bi-directional low-voltage racks (30) installed via a cradle (10) on one side of an electric pole in the state of excluding the mobile uninterruptible transformer car and the bypass cable that have been conventionally used when replacing a transformer. , B, C, and N phases connect low-voltage cables (1) and temporary cables (3) to ensure the stability of uninterruptible power supply, thereby simplifying high-voltage work to prevent safety accidents and shorten construction time. It has the advantage of reducing labor costs.

On the other hand, the present invention is not limited to the above-described embodiments, but can be practiced with modifications and variations within the scope of the present invention, and the technical idea to which such modifications and variations are applied also falls within the scope of the following claims. Must see.

1: low voltage cable 3: temporary cable
10: cradle 20: bracket
30: bidirectional low pressure rack 32: rack case
32a: female thread 34: cover
40: switch unit 42: knob
44: rotary plate 50a: left connection terminal
52a: first threaded rod 54a: projection
50b: right connection terminal 52b: first screw rod
54b: projection 60a: left connection terminal
62a: second threaded rod 64a: sleeve
60b: right connection terminal 62b: second screw rod
64b: sleeve

Claims (1)

A cradle installed on an electric pole;
A plurality of rack cases each fixed to the cradle at regular intervals up and down;
Left and right connection terminals fixed at the center of the rack case at regular intervals on the left and right, respectively;
a switch unit installed in the center of the rack case to connect or disconnect the left connection terminal and the right connection terminal;
a metal left connection terminal coupled to the charging part of the low voltage cable and inserted through a conduit opened on the left side of the rack case to be connected to the left connection terminal; and
It includes a metal right connection terminal coupled to the charging part of the temporary cable and inserted through a conduit opened on the right side of the rack case to be connected to the right connection terminal,
The switch unit,
A bi-directional low-voltage rack structure comprising a; rotating plate for simultaneously connecting or separating the left connection terminal and the right connection terminal inside the rack case.

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